DETERMINATION OF ANTIBIOTIC RESISTANCE IN THE BACTERIAL COMMUNITY OF BOILING SPRINGS LAKE IN LASSEN VOLCANIC NATIONAL PARK By Carrie Lynn Hudson A Thesis Presented to The Faculty of Humboldt State University In Partial Fulfillment of the Requirements for the Degree Master of Science in Biology Committee Membership Dr. Patricia Siering, Professor, Committee Chair Dr. Jacob Varkey, Professor Dr. Mark Wilson, Associate Professor Dr. Jianmin Zhong, Associate Professor Dr. Michael Mesler, Professor, Graduate Coordinator December 2012 ABSTRACT Determination of Antibiotic Resistance in the Bacterial Community of Boiling Springs Lake in Lassen Volcanic National Park Carrie Hudson Boiling Springs Lake is a pristine, oligotrophic, acidic hot spring in Lassen Volcanic National Park. In 2008, 25 isolates from BSL were tested for resistance to 14 different antimicrobial compounds or a sub-set of the 14 antimicrobial agents. All isolates were resistant to at least two of the antimicrobials and some were resistant to six or more. This thesis project expanded upon the preliminary research to achieve the following goals: (1) determine the antimicrobial resistance profiles of 50 BSL isolates; (2) determine the minimum inhibitory concentrations for select multi-drug resistant isolates; (3) analyze microarray data obtained from Geochip 3.0 to assess the levels of antibiotic- and metal-resistance genes present and their phylogenetic origins; and (4) use PCR to screen selected BSL isolates for the presence of multi-drug resistant efflux genes. All 50 isolates that were screened were resistant to at least one antimicrobial compound with 74% being resistant to four or more. One hundred and twenty-four antibiotic-resistance genes and 221 metal-resistance genes were detected in BSL. The emrB/qacA efflux gene amplicon sequence was obtained from 20 of the BSL isolates and was found to be 99- ii 100% identical. This identity spanned species, genus, and phylum levels of taxonomic hierarchy. These results support the findings of other studies that multi-drug resistance is common in pristine habitats, and that pristine habitats are reservoirs of antimicrobial resistance genes. These results also suggest that the emrB/qacA gene has been horizontally transferred between the BSL isolates. iii ACKNOWLEDGEMENTS A special thank you to my advisor Dr. Patricia Siering for all of her guidance and support throughout this project, my committee members Dr. Mark Wilson, Dr. Jacob Varkey, and Dr. Jianmin Zhong, the Humboldt Extreme Acidiphile Team (HEAT) lab, Clayton Carey for all of his help during the first year of this project, and the National Science Foundation and the Howard Hughes Medical Institute for funding this project. iv TABLE OF CONTENTS ABSTRACT ........................................................................................................................ ii ACKNOWLEDGEMENTS ............................................................................................... iv CHAPTER 1: SITE DESCRIPTION AND PROJECT GOALS ........................................ 1 CHAPTER 2: LITERATURE REVIEW ............................................................................ 4 INTRODUCTION………………………………………………………………...4 POSSIBLE FUNCTIONS OF ANTIBIOTICS IN THE ENVIRONMENT…...…5 ORIGINS OF ANTIBIOTIC RESISTANCE DETERMINENTS AND THEIR SELECTION IN NATURAL ECOSYSTEMS……………………………………...……8 CHAPTER 3: ANTIBIOTIC RESISTANCE SCREENINGS ......................................... 16 INTRODUCTION……………………………………………………………….16 MATERIALS AND METHODS………………………………………………...19 Media and antibiotic preparations………………………………………..19 Isolation and identification of isolates………………………………...…22 Antibiotic resistance screenings…………………………………………24 Minimum inhibitory concentrations (MIC)……………………………..25 Antibiotic stability………………………………………………………26 RESULTS…………………………………………………………………….…27 Identity of isolates……………………………………………………….27 Antibiotic resistance screenings………………………………………...30 Minimum inhibitory concentrations (MIC)…………………………..…36 v DISCUSSION……………………………………………………………………38 Identity of isolates………………………………………………………..38 Antibiotic resistance screenings………………………………………….39 Minimum inhibitory concentrations……………………………………..46 Antibiotic stability……………………………………………………….47 CHAPTER 4: GENETIC ANALYSIS…………………………………………………..52 INTRODUCTION……………………………………………………………….52 MATERIALS AND METHODS………………………………………………..54 Geochip 3.0 microarray analysis………………………………………...54 Multi-drug resistance efflux genes………………………………………55 RESULTS………………………………………………………………………..52 Geochip 3.0 microarray analysis……………………………………...…56 Antibiotic resistance genes………………………………………56 Metal resistance genes………………..………………………….62 Multi-drug resistance efflux genes………………………...…….70 DISCUSSION……………………………………………………………………73 Geochip 3.0 microarray analysis…………………………………………73 Multi-drug resistance efflux genes……………………………………….76 CHAPTER 5: SUMMARY............................................................................................... 78 REFERENCES…………………………………………………………………………..79 vi LIST OF TABLES Table Page 1 Summary of antimicrobials utilized for this project 18 2 Antibiotic disc preparation 21 3 Identity of isolates 29 4 Screening results for pH 2.9, low nutrient isolates 31 5 Screening results for pH 2.9, medium nutrient isolates 32 6 Screening results for pH 2.9, high nutrient isolates 33 7 Screening results for pH 5.0 and 7.0 isolates 34 8 Minimum inhibitory concentration results 37 9 Summary of antibiotic resistance genes (ABR) detected in BSL and 61 averaged normalized signal intensities (NSI) for detected ABR genes on hybridization of 2004 and 2009 samples 10 Summary metal resistance genes (MR) detected in BSL and 69 averaged normalized signal intensities (NSI) for detected MR genes on hybridization of 2004 and 2009 samples 11 Distance matrix for emrB/qacA genes and 16S rRNA genes 72 12 Most probable number results 98 vii LIST OF FIGURES Figure Page 1 Percent of BSL strains resistant to each antimicrobial 35 2 Predicted structure of BceB signal transduction system and ABC 44 transporter translocator 3 Structure of ciproflaxin with arrow indicating N 49 1 4 Antibiotic resistance genes detected in BSL 59 5 Phylogenetic origins of detected antibiotic resistance genes 60 6 Metal resistance genes detected in BSL 67 7 Phylogenetic origins of detected metal resistance genes 68 APPENDICES Page 1 Antibiotics as a single carbon source 93 2 Most probable number (MPN) quantification of antibiotic resistant 96 bacteria from BSL viii 1 CHAPTER 1: SITE DESCRIPTION AND PROJECT GOALS Lassen Volcanic National Park is located in northeastern California at the southern end of the Cascade mountain range and harbors many hydrothermal features within its boundaries. One of these features is Boiling Springs Lake (BSL), an approximately 18,000 m2 hot spring where the average temperature of the surface water during the summer months (June-August) is approximately 52°C +/- 3°C, and the average pH value is 2 +/- 0.4 (116,118). The southern end of the lake contains continuously active bubbling springs and mud pots and is the hottest and most heterogeneous region of the lake with an average summer temperature of 65-95°C (118). Research since the mid- 1970’s has determined that BSL is a stable feature in terms of pH, temperature and area of coverage, although this is based almost exclusively on summer sampling. Recent remote sensing during the winter months (October-May, 2008-2010) has revealed a seasonal depression of temperature by 5-10° C along with transient and further temperature depressions during snow-fall followed by slow recovery (118). These results suggest that although BSL is stable over the long-term, seasonal variation does occur. Unlike many other low pH environments being studied in Yellowstone National Park and other regions, the water chemistry at BSL is one that is low in metals, with all metals except SiO and Al being present at very low concentrations (97,98). BSL is an 2 oligotrophic habitat with measurements of dissolved organic carbon (DOC) ranging from 2 0.3-1.2 ppm in 2000-2010 (97). NH + was found to be 1.43 ppm or ~44 μM; the 4 concentration of NO - was measured at less than 0.02 ppm, and PO 3- was undetectable at 3 4 less than 0.05 ppm (97,98). Past and current research has revealed BSL contains an exclusively microbial community, with novel species of Archaea and Bacteria being the most abundant phylotypes in clone libraries derived from sediment samples (116,118). The planktonic community consists primarily of well-characterized bacteria in the Actinobacteria and Aquificales phyla (118). Both the planktonic and sediment communities are low in species richness and evenness as assessed by the clone library analysis: e.g. only 22 phylotypes were detected in 3 libraries prepared from BSL water, and 2 of the phylotypes represented 69% of the total clones (n=235) (116, 118). In addition to the assessment of diversity and the chemistry of BSL, our laboratory began investigating issues associated with organismal and gene biogeography, physiology and evolution in extreme habitats including intra-population diversity and ecotype differentiation. In the summer of 2008, 25 isolates from BSL were tested for resistance to 14 different antibiotics and bacteriocins or a sub-set of the 14 antimicrobial agents (75): ampicillin, penicillin-G, vancomycin, bacitracin, nisin, kanamycin, streptomycin, gentamycin, tetracycline, trimethoprim, rifampim, sulfisoxazole, ciproflaxin, and chloramphenicol. All of the isolates were found to be resistant to at least 2 of the antimicrobial compounds with some resistant to 6 or more, and surprisingly, most of the strains were resistant to the completely synthetic antibiotic ciproflaxin. Since BSL is a pristine habitat devoid of agricultural and municipal run-off, we attributed the abundance of resistant phenotypes to be a secondary effect of living in the